Reactions of deprotonated ligands. V. Deprotonated tris

Vol. 7, No. 3, Murch 1968

DEPROTONATED TRIS(ETHYLENEDIAMINE)RHODIUM(III) I O N

537

CONTRIBUTION FROM THE DEPARTMENT OF CHEMISTRY, THEUNIVERSITY O F TEXAS AT AUSTIN, AUSTIN,TEXAS78712

Reactions of Deprotonated Ligands. V. Deprotonated Tris(ethylenediamine)rhodium(III) Ion1 BY GEORGE W. WATT

AND

PETER W. ALEXANDER

Received SePteinber 21, 1967 The deprotonated complex [Rh(en-H)~en]I has been shown t o act as a nucleophile in reactions with C&I, CHsBr, SOCl2, and SO&& and as a strong Lewis base in the reaction with BF3. A similar reaction of [Rh(en-H)s]with CH3I is described. The products of these reactions were isolated as crystalline solids and characterized by analytical, X-ray diffraction, and infrared spectral data as [Rh(en.CHa)aen]Is,[Rh(en.CHa)zen]Br~I, [Rh(en.CH3)3]11, [Rh(en.BFl)~en] I, / Rh(en)[(en.€I)zSOz]}CIzI, and {Rh(en)[(en,H)zSO]}ClzI. Possible structures of the products are discussed in terms of the infrared spectral data and reactivity toward hydrolysis.

Ewens and Gibson2 report that a coordinated sulfur atom such as that in mercaptide complexes commonly behaves as a nucleophile. They found that ,&mercaptoethylamine(diethyl)gold(III) reacts with methyl iodide to form the corresponding thioether. Such reactions have been extended to complexes of other metals, especially Ni and Pd with ligands of a similar nature, and represent an energy-transfer process. Methylation of the Ni-S-R group S atom which is quite strongly bound to the Ni atom produces the relatively weaker nickel-thioether bond, accompanied by a change from a square-planar diamagnetic complex to a paramagnetic octahedral one. With Pd(I1) analogs, methylation decreases the M-S bond strength to such an extent that one ligand is lost to give the product [Pd(NH2CH2SCH3)Iz1. Reactivity of coordinated mercaptides has shown3 that terminal groups exhibit a greater tendency to act as nucleophiles than do bridging groups, but the nucleophilic power of a sulfide group is greatly impaired by replacing Ni(I1) with Pd(II), an ion with little tendency for pentacoordination. Reactions of this type have been successfully employed to prepare complexes containing macrocyclic rings. The product of the reaction between bis(P-mercaptoethylamine)nickel(II) and biacetyl, ;.e., 2,2’ - dimethyl(ethanediylidenedinitri1o)(diethane)thiolnickel(II), reacts with 1 mol of a,a’-dibromo-oxylene to give a product in which the Ni ion is completely enclosed by rings. Similar reactions with trimethylene diiodide and ethylene dibromide have not met with equal success perhaps because the ethylene dibromide is too short to span the distance between the S atoms. Much of the work involving mercapto complexes has been summarized in a recent re vie^.^ The nucleophilic properties of atoms other than sulfur coordinated to metals are less well known even though proton dissociation from oxygen and nitrogen (1) Abbreviations: en = ethylenediamine; (en-H) = deprotonated en ligand; (en. CHs) = (en-H) methylated a t the deprotonated N atom; men = N-methylethylenediamine; dien diethylenetriamine; bipy = 2,2’-bipyridyl. (2) R. V. G. Ewens and C. S. Gibson, J . Chem. Sac., 431 (1949). (3) D. H . Busch, J. A. Burke, D. C. Jicha, M. C. Thompson, and M. L. Morris, Advances in Chemistry Series, No. 37, American Chemical Society, Washihgton, D. C., 1963, p 125.

has long been k n o ~ n . ~Coordinated ?~ aquo ions such as [Cr(H20)6]a+ have been shown4 to be reasonably acidic in aqueous solution as have certain ethylenediamine complexes of A u ( I I I ) ~and OS(IV).~ Acid dissociation constants of some en complexes have been measured in aqueous solution, e . g .

e [Pt(en-H)en~]3++ H +

[Pt(en)3l4+

where pK, is reported’ to be 4.0, but in many cases the pK, values are too large to be measured in aqueous solution. It has been shown8 that, by working in solvents more basic than water, ammine complexes which are apparently not acidic a t all in aqueous solution can be deprotonated in these solvents. The conjugate bases of such complexes should exhibit much stronger nucleophilic tendencies than complexes containing sulfur, oxygen, or nitrogen donor atoms with much lower pK, values. Watt and Upchurchg have methylated the deprotonated square-planar Pt(I1) complexes [Pt(bipy)(en-H)]I and [Pt(bipy) (en-2H1, where a a-bonding ligand is trans to the deprotonated N atoms of en. Solid products were characterized as [Pt(bipy)(en.CH3)]12and [Pt(bipy)(en.2CH3)]12. Such reactions have been extended1” to the octahedral system, [ C ~ ( e n - H ) ~ e n ]not I , involving a r-bonding ligand. The present paper describes nucleophilic substitution reactions of the Rh(II1) octahedral complexes [Rh(en-H)a(en)]I and [Rh(en-H)B].

Experimental Section The equipment and procedures for reactions in liquid ammonia have been described previously.“ Hygroscopic or air-unstable products were stored and handled in a drybox containing a helium atmosphere maintained oxygen and water free by continuous exposure to liquid Na-K alloy. (4) J. C. Bailar, Jr., “Chemistry of the Coordination Compounds,” Reinhold Publishing Corp., New York, N. Y . , 1956. (5) B. P. Block and J. C. Bailar, J . Am. Chem. Soc., 73,4722 (1951). (6) F. P. Dwyer and J. W. Hogarth, ibid., 76,1008 (1953). (7) A. A. Grinberg, L. V. Vrublevskaya, Kh. I. Gel’dengershel, and A. I. Stetsenko, Zh. Neovgan. Khim., 4, 1018 (1959). (8) G. W. W a t t , el at., J . Am. Chem. Soc., 79, 5163 (1957); 81, 8 (1959); 82, 4465 (1960); I n o v g . Chem., 1, 6 (1962); 4, 143 (1965). (9) G. W. W a t t and D. G. Upchurch, J . A m . Chem. Soc., 87, 4212 (196rj). (10) G. W. W a t t , P. W. Alexander, and B. S. Ivfanhas, ibid., 39, 6483 (1967). (11) G. W. W a t t , et al., J. Inovg. Nucl. Chem., 9, 311 (1959); J . Electuochem. SOL.,98, 1 (1951); 102, 46,454 (1955).

1novgci nic Cizcmistry Standard methods of analysis were used in all cases. Infrared spectra were obtained with a Beckman IR-7 instrument with CsI interchange optics. Spectra were taken as potassium iodide disks in the range 270-4000 cm-I. Ultravioletvisible spectra were measured with a Cary Model 14 recording spectrophotometer using matched 1-cm quartz cells. The resulting data are listed in Table I. TABLE

1

INFRARED SPECTRAL DxrAa I

I1

3180 vs 3090 vs 2980 sh 2900 sh 1565 s , br 1485 sh 1459 s 1396 w 1366 m 1327 m 1300 m 1279 w 1230 w 1210 w 1154 s 1120 m 111.5 sh 1056 s 1000 m 955 m 929 w 877 m 834 w 880 m, br 783 sh 758 sh 572 m 559 m 498 m 418 m 350 ms 250 ms

3200 vs, br 3100 vs, br 2980 sh 2895 sh 1585 sh 1567 s , br 1475 sh 1461 s 1399 w 1367 m 1330 m 1300 m 1279 m 1230 w 1213 w 1155 s 1125 m 1115 sh 1057 s 1000 m 957 m 925 w 880 m 858 v w 835 v w 790 m, b r 573 m 657 w 503 m 498 sh 446 m 353 m

I11

v

3180 vs 3090 vs 2980 sh 2895 sh 1575 s, br 1485 s h 1460 s 1420 m 1400 w 1366 m 1329 m 1300 m 1280 w 1230 sh 1211 w 1154 s 1121 m 1114 sh

3200 vs 3105 vs 2980 sh 2900 sh lS72 s, br 1459 s 1397 m 1366 m 1324 m 1268 s 1263 s 1210 m , bi 1150 s 1118 s, br 1055 s 1030 sh 1000 m 880 m TDO sh 774 m 740 w

IV 3320 m 3180 vs 3090 v s 2980 sh 2895 sh 1573 s, br 1462 s 1430 s, br 1398 ms 1373 m 1329 m 1304 m 1282 sh 1235 w 1210 w 1150 s 1117 Y S 1076 vs 1056 s 1055 vs 1000 m 1038 sh 955 m 1000 vw, sh 926 w 881 m 800 sh 878 w 858 v w 110 m 832 w 760 w 803 m, br 665 w 571 m 780 sh 730 "W 555 m 530 m 574 m 558 sh 523 sh 500 m 502 m 445 m 449 w 352 m 352 m 255 s 250 s, br

VI 3190 vs, br 3100 vs, br 2980 sh 2900 sh 1570 s, br 1457 s 1397 w 1366 m 1325 m 1265 s 1213 m 1152 s 1108 m 1058 vs 1032 sh 1005 w 878 m 806 s 745 v w 705 w 623 m, sp 596 w 573 m 557 m 501 m 448 m 403 w 354 m

'r.4BLE 11 X-RAYDIFFRACTION DATA"

7-1-

7-11-

I/ d, I / A Io A Io 9.93 0.6 1 0 . 2 7 1 . 0 4 2 8 1.0 6.630.8 3.81 0 . 7 6 . 2 5 0.7 3.61 0 . 4 4.20 0 . 7 3.41 1 . 0 3 . 9 8 0 . 7 3.23 0 . 7 3.670.9 2.27 0.4 3.450.8 3.30 0 . 8 1.9,s 0.n (1,

'I

--I111 d, I / Io 7.160.7 5.820.2 4.58 0 . 3 4.31 1 . 0 4 150.1 3780.3 3.440.5

c--v--.

--IV--.

d,

a

a

I/

Io

7.790.8 6.781.0 6.60 0 . 8 5.14 0 . 7 4.29 0.9' 4 0 7 0 6 3.920.8 3.83 0 8 2.95 0.6

LCSSintcnse lines not includcd.

d,

a

---vc---.--. I/

d,

Iu

A

10.520.3 6.O21.Ob 5.50 0 . 7 4.41 0 . 5 3.93 1 0 3.700.4 3.480.5' 2.94 0 . 3

I/ Io

6.170.8" 5.111.0" 4.54 0 . 2 4 07 0 . 4 3.87 0 . 4 8.55O.X

3.340.3 2.49 0.2

Broad line.

distillatioil aud tlie residual solid dried in Y U C Z I U for 21 lir. l'lic product was yellow-tan and appeared stable in air. A n d . Calcd for [Rh(en.CH3)ien]Ig (I): Rh, 14.9; C, 13.9; H, 4.05. Found: Rh, 15.0; C, 13.8; H, 4.26. This product was soluble and stable in water, The ultraviolet-visible spectrum showed two maxima at 270 and 345 mp (E -900 and 300, respectively); the spectrum did not change with time. Reaction of [Rh(en-H)zen]I with Methyl Bromide.-Gaseous CHgBr was condensed a t reduced pressure and -72' in a reaction vessel which had previously been evacuated and contained 0.3 g of [Rh(en-H)nen]I. The reaction vessel was sealed and the mixture stirred a t 25" for 2 months, and, as in the previous reaction, the solid changed from pale yellow t o yellow-tan. Excess CH8Br was removed by distillation and the residue was dried in zacuo TOO w for 24 hr. The product was stable in air b u t slightly hygroscopic. 623 s Anal. Calcd for [Rh(en.CHt)pen]Br~I(11): Rh, 17.2; C, 16.1; 598 m 5i5 m H , 4.70. Found: R h , 17.1; C, 16.3; H, 5.07. 560 m Reaction of [Rh(en-H)3] with Methyl Iodide.-A samplc of 500 m 0.5 g of [Rh(en-H)~] was treated with a large excess of CH3I as 450 m described above for the methyl iodide reaction. The mixture was 403 w 355 m stirred continuously for 1 month at 25" and the excess CHgI removed by distillation. After drying i n z~acuofor 24 hr, tlie remaining solid was n.ashed with two 50-ml portions of anhydrous ether b v distillation of the ether i n oacuo into the reaction vessel. T h c ether was filtered off, and the solid dried once more for 24 Iir a Symbt11s: vs, very strong; s, strong; llls, mcdiulll strotlg; in vacuo. The product was yellow-tan and appeared stable i i i sp, siiarp; br, broacl; trl&jiurrl; Jv, weak; vw, very shoulder. air b u t slightly hygroscopic. Anal. Calcd for [Rh(en.CH3):4]l a (111): Rh, 14.6; C, 15.3; H, 4.25; I, 54.0. Found: Rh, 14.4; C, 15.0; H , 4.12; I, 53.9. This product dissolved in water to X-Ray diffraction data were obtained using Cu Kor radiation form a solution, the ultraviolet-visible spectrum of which did not (Ni filter), 35-kV tube voltage, 15-mA filament current, and change with time. Maxima were observed at 276 and 352 mp 13-15-hr exposure times. Relative intensities were estimated ( E -1800 and 700, respectively). visually. The data are given in Table 11. Reaction of [Rh(en-H)%en]I with Boron Trifluoride.--.kpMaterials.-With the folloiving exceptions all materials emproximately 10 in1 of chloroform, followed by 20 ml of anhydrous ployed were reagent grade chemicals t h a t were used without ether, was distilled in uacuo into a reaction vessel containing 0.8 further purification. g of [Rh(en-H)een]I. Gaseous BFI was bubbled through tlie Tris(ethylenediamine)rhodium(III) Iodide.-The method of solvent until manometer pressure readings indicated that the preparation of [Rh(en)3]13 has been described by Watt and solvent mixture was almost saturated. The solution tuructl Calcd for [ R h ( e n ) ~ ] I ~ : Crum;12 the yield was 487;. .Anal. orange in color and was allowed to stir For 5 days. After filtration, R h , 15.5; I, 57.3. Found: Kh, 15.3; I, 57.3. a yellow-orange solid was obtained, washed in vacuo with tlirec Deprotonated Complexes.-Deprotonation was carried out by for 24 lir. 50-ml portions of anhydrous ether, and dried in zlucu~~ the method described elsewhere.12 Titration of [ R l ~ ( e n I3 ) ~with ] The product appeared stable in air but was slightly hygroscopic. 2 molar equiv of KNH2 in liquid ammonia gave pale yellow, Anal. Calcd for [Rh(en.BF~)pen]I(IV): C, 13.3; H, 4.05; insoluble [Rh(en-H)%en]I. Anal. Calcd for [Rli(en-H)~en]I: I, 23.3. Found: C, 13.4; H, 4.50; I, 23.4. The infrared R h , 25.2; I , 31.1. Found: R h , 25.6; I , 31.3. spectrum is shown in Figure 1. An aqueous solution of this Titration of [Rh(en)3]13 with 3 molar equiv of KSHz in product was initially pale yellow but became colorless almost liquid ammonia gave yellow, insoluble [ R l ~ ( e n - H ) ~ ] Anal. . immediately. This solution gave a n ultraviolet spectrum v i t h Calcd for j R h ( e ~ ~ - H ) ~Rh, l : 36.7; I, 0.0. Found: R h , 36.6; only one band at 300 mp. ,,,, I, U.U. Reaction of [Rh(en-H),en]I with Sulfuryl Chloride.-FracBoth of these complexes are unstable in air and were stored and tional distillation of S02Clr: was used to remove a low-boiling sampled in a dry helium atmosphere. yellow impurity. The reagent (ca. 20 ml) was then added by Reaction of [Rh(en-H)nen] I with Methyl Iodide.-Apdistillation in vacuo to a 0.7-g sample of [Rh(en-H)~en]I. The proximately 20 ml of CH3I was added by distillation in cacuo to pale yellow coniplex changed to briglit yellow almost immedia*ely, 0.2 g of [ R l ~ ( e n - H ) ~ e nin] Ia reaction vessel containing a magnetic a n d , after stirring for 1 day at 25O, excess SO2CI2 was removed by stirring bar. The vessel was sealed and the reaction mixture filtration. T h e remaining solid 'uvas dried in C'QCUO for 24 hr, stirred for 3 weeks at 2 5 " . The excess CH3I was removed by washed in vacuo with two 50-ml portions of anhydrous etlicr, and dried in "v'cuo for 24 lir. The product was a bright yellow, fiucly (12) G . W, Watt a n d J. K. Cruin, J . A??&. Chem. SOL.,87, S t i O (1Uti5).

--.

DEPROTONATED TRIS(ETHYLENEDIAMINE)RHODIUM(III) ION 539

Vol. 7, No. 3, March 196.5’

d

0 z 4

m C Y

w

m

i 4000 3600 3200 2800 2400 2000 I900 I800 1700 I600 1500 1400 1300 1200 1100 I000 900 800 700 600 500 400 300 200

D icrn.1) Figure 1.-The

infrared spectrum of [Rh(en.BF3)een]I: (a) 0.3% in K I ; ( b ) 1.0% in K I .

divided powder, stable in air, but slightly hygroscopic. Anal. Calcd for { Rh(en)[(en-H)zSOe]}CLI (V): Rh, 18.9; C, 13.3; H , 4.05; N, 15.4. Found: Rh, 18.5; C, 13.1; H , 4.27; N, 15.4. The infrared spectrum is shown in Figure 2. A pale yellow aqueous solution of this product gave a n ultraviolet-visible spectrum with bands a t 297 and 455 m p ( E -500 and 280, respectively). Over 1 week the solution became colorless and this solution exhibited one band a t 300 mp. The spectrum of a solution prepared and stored under nitrogen showed very little change after 1 week. Reaction of [Rh(en-H)zen]I with Thionyl Chloride.-Approximately 0.5 g of [Rh(en-H)nen]I was treated with excess Socle (20 ml) as described for the foregoing reaction. The pale yellow solid immediately began to turn to a darker yellow, and, after stirring for 24 hr a t 25O, the solid was filtered and dried in ZIUCUO for 24 hr. The product was a finely divided orange powder; in air, it slowly decomposed and after exposure for 1 week turned black. Anal. Calcd for { Rh(en)[(en-H)zSO] } ClzI (VI): Rh, 19.52; C, 13.66; H , 4.21; N, 15.94. Found: Rh, 19.87; C, 13.37; H , 4.16; N, 15.67. The ultraviolet-visible spectrum of a n initially pale yellow aqueous solution of this product showed bands a t 288 and 348 mp and a broad band a t ca. 450 mp ( E -900, 500, and 150, respectively); this spectrum remained unchanged when the solution was stored under nitrogen for 3 days. I n the presence of air, however, the solutions became colorless on standing overnight and the spectrum consisted of only one band a t 300 mp.

Discussion Analytical data for the solid products described above reveal the following stoichiometry. The mole ratio of [Rh(er~-H)~en]I to reagent is 1:2 with 1: 2 with CH3Br, 1: 1 with SOZC12, 1: 1 with SOCIz, and 1:2 with BF3. The mole ratio of [Rh(er~-H)~] to reagent has been shown to be 1:3 with CH31. The X-ray diffraction data in Table I1 were obtained to supplement the characterization of the reaction products and, by comparison with analogous data for the deprotonated species, to provide the initial evidence for the occurrence of reaction with the various reagents. I n Table I are listed the band positions and relative intensities in the infrared spectra of the reaction products. These spectra provide evidence for the presence of the attacking groups in the solid products and partial assignments have been made. As might be expected, modification of only a small part of the tris(ethylenediamine) structure in these reactions does not alter the over-all spectral features to any great extent, and the main skeletal vibrations of [Rh(en)3]13 are still obvious in the spectra of the reaction products. However, the appearance of new bands can be attributed t o the presence of the added groups.

-

The spectrum of [Rh(en CH3)een]13exhibits several bands not present for [Rh(en)3]13or [Rh(efl-H)zen]I. These appear a t 1485 sh, 1396, 1230, 955, 929, and 834 cm-l, and are assigned by comparison with the roughly similar ions (CH3)zNH2+and (CH3)3NH+ studied by Ebsworth and Sheppard.la They assigned bands near 1470 and 1400 cm-l as asymmetric and symmetric bending deformations of CH3and on this basis similar assignments are made for the bands a t 1485 and 1396 cm-l of the methylated product. The bands a t 1230 and 955 cm-I are then assigned by the same correlations as CHQrocking motions and those a t 929 and 834 cm-l as C-N stretches. Previous work’* on diethylenetriamine complexes of Pd(I1) is also in agreement with the assignment of v(C-N). The N H bending deformations for [Rh(en)3]13have been assigned a t 1580 and 1550 cm-I. For the methylated complex only one strong, broad band appears in this region a t 1565 cm-l. I n all other respects, the spectrum closely resembles that of [Rh(en)3]13and of particular interest are the Rh-N stretching modes a t 572 and 559 cm-l, not significantly different from v(Rh-N) for the en complexlZa t 570 and 558 cm-I. The methyl bromide reaction product, as expected, exhibits a spectrum virtually the same as that of [Rh(en.CH3)zen]13 as shown in Table I. The one noticeable difference concerns the intensities of the Rh-N stretching vibrations where there is an increase in the relative intensity of the band near 570 cm-l with respect to that of the band a t 557 cm-l. For [Rh(en)3]13, the band a t the lower wavenumber is the more intense whereas for both methylated derivatives the opposite is true. Somewhat surprisingly, the spectrum of [Rh(en CH3)3]13 (111) is similar in nearly every respect to those of the two complexes discussed above. A medium band appears a t 1420 cm-I which seems likely13-16 to be due to the NH bending deformation of the secondary amino grouping, CH3-NH. N substitution of the third methyl group is apparently required to produce the increase in intensity necessary to observe this band. I n the absence of deuteration experiments, little certainty can be attached to this assignment, however. The Rh-N stretches are also significantly (13) E. A. V. Ebsworth and N. Sheggard, Spectrochim. Acta, 13, 261 (1959). (14) G. W. W a t t and D. S. Klett, ibid., 20, 1053 (1964). (15) L. J. Bellamy, “The Infrared Spectra of Complex Molecules,” John Wiley a n d Sons, Inc., New York, N. Y., 1958, p 257.

540 GEORGE W. WATTAND PETERM'. ALEXANDER

Inorganic Chemistry

W

0

5 z

m

IL

E m

i 4000 3600 3200 2800 7400 PO00 19C0 I9CG 1700 I600 1500 1400 1300 I200 I100 I000 900 8C0 700 600 500 403 300 230 0 (cm 1 )

Figure 2.-The

infrared spectrum of

affected since a large increase in intensity of the 573cm-I band was observed while the band a t 558 cm-I appears only as a weak shoulder. These are the only obvious spectral changes brought about by the reaction of 3 mol of CH3I with [Rh(er~-H)~].The reasons for this close similarity between spectra of the diand trimethylated products is not clear when i t is considered that the infrared spectrum16 of [Rh(men)3]13, prepared by direct synthesis, is distinctly different from any of the spectra discussed here. This point is discussed further below. The spectrum of [Rh(en.BF3)2en]I(IV) is reproduced in Figure 1 and band positions are listed in Table I. The presence of BF3 is clearly indicated by the extremely strong absorption in the range 10301150 cm-1 characteristic of boron-fluorine vibrations." The BF3 molecule is planar and belongs to the D 3 h point group. On coordination to a deprotonated nitrogen atom of the Kh(II1) complex, formation of the tetrahedral [NBF3]- group is expected, with consequent lowering of symmetry to Csv as a first approximation to the local symmetry of the BF3group although the real symmetry in the molecular framework is probably C1. The number of infrared-active normal vibrations is then increased from four for BF3 to six18 for molecules of type ZXY3. Three of these are easily assigned by comparison with the spectrumlg of "3. BF3 so that the bands a t 1117 and 1076 cm-1 are the v4(E) fundamentals of the loB and IIB isotopes and those a t 1055 and 1038 cm-l are the V I ( & ) frequencies. The doublet a t 523 and 530 cm-I is the vj(E) fundamental of the BF3 bending deformation; the splitting has been attributed" in [BF4]- to the isotopic effect of 1°B and IlB. The VQ(Al) fundamental was not observedlg in the infrared spectrum of "3. BF3 but was foundlg a t 450 cm-I in the Raman spectrum, while v ~ ( E ) the , rocking mode, was assigned a t 330 cm-l. Neither of these modes is obvious in the spectrum of complex IV and apparently they are both obscured by en skeletal vibrations in these regions. This leaves the vz(A1) frequency for the B-N stretching vibration unassigned, and there is a very wide spread in the frequency values assigned for similar compounds such as 735 cm-l for NH3.BF3,I9 (16) G. W. W a t t and P. W. Alexander, J . A m . Chem. Soc., 8 9 , 1814 (1967). , (1959). (17) N N. Greenwood, J . Chem S O L 3811 (18) K. Nakamoto, "Infrared Spectra of Inorganic and Coordination Compounds," John Wiley and Sons, Inc , Xew York, N. Y . , 1963, p 110. (19) J. Goubeau and H. Nitschelen, 2. Physzk. Chem., 14, 61 (1958).

{ Rh(en)[(en-H)G3O.J )C12I.

1113 cm-I for the py-BCls adduct,201249 cm-' for (CH3)gN.BF3,21 and 1255 cm-I for (CH3)3N.BH3.22 This latter assignment, however, has been found doubtful by Taylor and who, from Raman spectroscopy, propose that v(B-N) occurs a t 667 cm-I. For the Rh(II1) complex, two other bands appear which are not present in the starting materials, v i z . , a strong, broad band a t 1430 cm-I and a weak band a t 630 cm-l. It seems likely from the "3. BF3 assignmentslg that the band a t 1430 cm-I is the NH bending deformation of the BF3.NH group, and we therefore assign 665 cm-I as v(B-N). In other respects, the spectrum of [Rh(en.BFa)en]I resembles that of [ R h ( e r ~ ) ~and ] I ~ again the Rh-N stretching modes a t 571 and 555 cm-I are virtually unchanged. The infrared spectrum of {Rh(en)[(en-H)zSOs]]ClJ is given in Figure 2 and the band positions are listed in Table I. Assignments have been made by comparison with the spectra of sulfuryl chloride and sulfamide as reported by Robinsonz4 and by Martz and Langeman. z5 A straight-line correlation was founds4 between the symmetric and antisymmetric stretching frequencies of the SO2 group contained in a wide variety of compounds. In addition, v ( S 0 ~ ) was found to increase with the electronegativities of the attached groups, X and Y, in XYSOz, thus indicating an increase in the strength of the S=O bonds. For example, v,(SOz) and v,(SOz) are found, respectively, a t 1501 and 1269 cmP1for SO2F2, 1414 and 1182 cm-l for SO2C12, and 1350 and 1163 cm-I for S O Z ( N H ~ ) ~ . ~ ~ For the Rh(II1) complex reaction product with SOzCI,, strong bands are observed a t 1268 and 1118 cm-' which lie close to the straight-line plot of Robinson. The relative intensities of these bands are considerably more intense than those observed in this range for [Rh(en)g]Ia and they are therefore assigned as Y , ( S O z ) and v,(S02), respectively. It is interesting to note that the bands occur a t frequencies significantly lower than those for sulfamide. The low frequencies of these vibrations provide evidence for the bonding of S to two N atoms. The remaining characteristic changes in the spectrum occur in the far-infrared region with the ap(20) N. N. Greenwood and K. Wade, J . Chem. SOL, 1130 (1960). (21) A. R. Katritzky, ibid., 2049 (1959). (22) B. Rice, R. J. Galiano, and W.J. Lehmann, J . Phys. Chem., 61, 1222 (1957). (23) R. C. Taylor a n d C. L. Cuff, Nature, 182, 390 (1958). (24) E. A. Robinson, Can. J . Chem., 8 9 , 247 (1961). (25) D. E. M a r t z a n d R. T. Larigeman, J . Chem. Phys., 22, 1193 (1954).

Vol. 7, No. 3, March 1968

DEPROTONATED TRIS(ETHYLENEDIAMINE)RE-IODIUM(III) ION 541

pearance of a strong, sharp band a t 623 cm-I, and less intense bands a t 598 and 403 cni-l. Assignments in this region are complicated by possible overlap with the metal-ligand vibrations and the large number of bands predicted for the XZSOZ system (where X = C1, NH2, etc.). For tetrahedral molecules of this type, the symmetry is Cz, and nine infrared-active normal vibrations are expected.l8 All of these bands have been found for S02Cl2, and seven occur in the region 250600 cm-'. I n the spectrum of the complex, the band a t 623 cm-1 is most characteristic but is absent in the spectrum of SOZC~Z.By comparison with literature values for other molecules, this band is assigned as an S-N stretching frequency. There is some uncertainty in the literaturez6 as to the frequency range expected for v(S-N), but i t has been assigned a t 550 cm-' for sulfamide2' and a t 688 cm-l for NH3.S03,** and the several S-N vibrational modes of the cyclic S4N4 have been assigned29 in the region 460-790 cm-'. The origin of the remaining bands a t 598 and 403 cm-I is uncertain. As for the previous products, there is again very little change in v(Rh-N), observed a t 575 and 560 cm-l, for the SOzClz reaction product. The spectrum of the thionyl chloride reaction product (VI), {Rh(en)[(en-H)zSO])Cld, is very similar to that of the sulfuryl chloride product; the band positions and intensities are listed in Table I. Assignments for thionyl chloride have been reported,30 the S-0 stretching frequency occurring a t 1229 cm-l and the asymmetric and symmetric stretching frequencies S-C1 a t 490 and 443 cm-l. Several bands appear in the spectrum of the complex, not observed in either [Rh(en-H)zen]I or [Rh(en)3]13, a t 1265, 623, 596, and 403 cm-l. By comparison with SOC12, the strong band at 1265 cm-l is assigned as v(S-0) at a somewhat higher frequency than for thionyl chloride, thus indicating an increase in the S-0 bond strength on coordination of the S atom with the N atom nucleophile of the deprotonated complex. The far-infrared region is remarkably similar to that observed for the sulfuryl chloride reaction product, and the band a t 623 cm-l is again assigned as an S-N stretching vibration. The origin of the bands a t 596 and 403 cm-I remains uncertain. With regard to the comparative stabilities of the products of concern here, the methylated species are stable both in air and in aqueous so1ut:on. The products of reactions with BF3 and SOzClZ are stable in air but the SOClz reaction product decomposes slowly. All three of these products are somewhat hygroscopic and undergo hydrolysis in aqueous solution to form colorless solutions the ultraviolet-visible spectra of which show only a band a t 300 mp that is characteristic (26) J. N. Baxter, J. Cymerman-Craig, and J. B. Willis, J . Chem. Soc., 669 (1955). (27) H. J. Hoffmannand K. R. Andress, Natuuwissenschaftsn, 4, 94 (1954). (28) T. J. Lane, I. Nakagawa, S. I. Mizushima, A. J. Saraceno, and J. V. Quagliano, Spedrochim. Acta, 12, 239 (1958). (29) E. R. Lippincott and M. C. Tobin, J. Chem. Phys,, 2 1 , 1559 (1953). (30) R. J. Gillespie and E. A. Robinson, Can. J . Chem., 89, 2171 (1961).

of [Rh(en)3]3+.31 Hydrolysis is almost instantaneous for the BFa product and less rapid for the SOpCls and SOClz products; in both of the latter two cases, hydrolysis can be inhibited by exclusion of oxygen. The relatively greater stability of the SOzClz product suggests that the hydrolysis of the SOClz product in the presence of air is accompanied by an oxidation step which evidently increases the rate of hydrolysis. Such a step cannot occur when air is excluded from the solution or in the case of the SOzClz reaction product, a solution of which hydrolyzes only very slowly even in the presence of air. Conclusive evidence concerning the structures of these complexes is not yet available. The analytical, X-ray diffraction, and infrared spectral data demonstrate that reaction between the deprotonated Rh(II1) complexes and the added reagents occurred with established stoichiometry and provide data concerning the mode of bonding in the reaction products. To obtain direct evidence of structural configuration would require synthesis by other routes which has not been found possible. The present syntheses are therefore useful for preparing such complexes which cannot be prepared by other methods. The reaction products with C&I, SOzClz, and SOClz are analogous to those reportedlo for [Co(en-H)zen]I, and their properties are similar. I n connection with the methylated Co complex, it was suggested that two methyl groups reacted with two different en molecules a t the deprotonated N atom nucleophiles in cis positions. The cis configuration could be present initially or be formed by anionic site migration. The synthesis of [Rh(en.CH3)3]Is now indirectly indicates that this suggestion is plausible since this product is not identical with [Rh(men)3]13 prepared directly16by reaction of RhCl3 with N-methylethylenediamine. The latter product could have structure a wherein the three methyl groups are in cis positions. Another geometric isomer, structure b,

r

CH3

1

L

J

a

b

could then be assigned to the [Rh(en.CH3)3]13prepared in the present work, thus accounting for the observed differences in X-ray, infrared, and ultraviolet-visible data, although geometric isomerism is not normally associated with such significant changes in the infrared region. The nucleophilic reaction with the sulfur compounds could occur with bridging of two deprotonated nitrogen atoms of the complex by the sulfur atom, as suggestedlO for the analogous Co complexes. The (31) C. K. JZrgensen, Acta Chem. Scand., 10, 500 (1958).

Ei42 J. T. MAGUEAND G . WILKINSON

two chlorine atoms of either S02Clzor SOC1, are then replaced by two deprotonated Ki atoms of the en complex. For bridging to occur in this manner, the two N atom nucleophiles would be required to occupy a cis configuration a t some stage during the reaction. The infrared data support these conclusions since S-N stretching frequencies are observed and the SOz stretching frequencies are shifted to much lower values in comparison with those of SO2C12. The S-N stretch in {Rh(en)[(en-H)zSO])ClzI occurs a t approximately the same frequency as for the sulfuryl chloride reaction product. However v ( S 0 ) a t 1265 cm-' is higher than the corresponding vibration for SOClz indicating an increase in the double-

Inorganic ChPmistry bond character of the (S=O) group. The influence of resonance hybrid structures responsible for this effect apparently contributes to the instability in air. The nucleophilic properties of the deprotonated N atoms in [Rh(en-H),en]I are further demonstrated by its ability to act as a Lewis base toward boron trifluoride. Although Watt and Crum have sho-vvn12that delocalization does occur to some extent, the deprotonated site must retain a substantial electron density in order for this reaction t o proceed. Acknowledgments.-This work was supported by the Robert A. Welch Foundation and the C . S.Atomic Energy Commission.

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CONTRIBUTION FROM THE DEPARTMENT OF CHEMISTRY, IXPBRIAL COLLEGE, LONDON, EXGLAND, A N D THE DEPARTMENT O F CHEMISTRY, TULANE USIVERSITY, XET ORLEANS, LOUISIANA701 18

Fluorocarbon Complexes of Rhodium Containing Triphenylstibine and Triphenylarsine BY J. T. MAGUE

AND

G. WILKTNSOS

Receioed October 5, 1967

Tris(triphenylstibine)chlororhodium(I) reacts readily with tetrafluoroethylene to produce the complex RhCl(C2F*)(Sb(C6H5)3)2. With hexafluorobut-2-yne, the complexes RhCl(CaF~)(Sb(CsH5)3)3and R ~ C I ( C ~ F I ~ ) ( S ~ ( are C ~ formed. H~)~)~ The latter five-coordinate complex contains a rhodiacyclopentadiene ring and being coordinatively unsaturated for rhodium(111) readily forms adducts with donor molecules such as carbon monoxide, phosphorus trifluoride, and pyridine. An analogous rhodiacyclopentadiene derivative is formed from tris(triphenylarsine)chlororhodiurn(I) and hexafluorobut-2-yne.

Introduction The large variety of substitution and oxidative addition reactions undergone by the versatile hydrogenation catalyst tris(tripheny1phosphine)chlororhodium(I) suggested that similar results could be obtained with the analogous triphenylarsine and triphenylstibine complexes.2 I n view of the enhanced stability of a number of the derivatives of the complexes RhC1(M(C6H6)J3 (M = As, Sb) over that noted for the analogous triphenylphosphine-containing complexes2 it was hoped a wider range of derivatives could be prepared from these. Experimental Section Microanalyses were by the Microanalytical Laboratory, Imperial College, London, A. Bernhardt, Muhlheim, Germany, and Galbraith Laboratories, Inc., Knoxville, Tenn. Molecular weights were determined on a Mechrolab osmometer a t 37". Infrared spectra were recorded using Beckman IR-5A and GrubbParsons Spectromaster instruments on Nujol mulls unless otherwise stated. All of the compounds reported contain absorptions due t o triphenylarsine or -stibine; thus only additional bands are reported. Kmr spectra were taken on a T'arian HR-60 spectrorneter in chloroform solutions. The 19Fresonances are referred t o benzotrifluoride as an internal standard. Melting points were

(1) J. A. Osborn, F.H. Jardine, J. F.Young, and G.Wilkinson, J . Ckewt. Soc., S a l . A , 1711 (1966). (2) J. T.Mague and G.Wilkinson, ibid., 1736 (1066).

determined on a conventional hot-stage microscope and are uncorrected. The benzene used was distilled from calcium hydride and stored over sodium. Dichloromethane was distilled from calcium chloride and stored over the same. RhCI( CpF,)(Sb( C~HF,)~)A.--~& dichloromethane solution ( 5 ml) of RhCl(Sb(C6H,)3)3 (0.3 g ) was placed in a thick glass tube which was then frozen and evacuated. Tetrafluoroethylene was condensed in and the tube sealed. The tube was shaken for ca. 0.5 hr at room temperature, at the end of which time yellow-orange crystals of the complex had formed (mp 154-156'). These mere collected, washed with diethyl ether, and air dried (yield 0.2 g , S570). Recrystallization was effected from hot 1,l-dichloroethane. Anal. Calcd for CBsH&bzF4C1Rh: C, 48.3; H , 3.2; mol wt, 945. Found: C , 48.7; H , 3.7; mol w t , 927 (CHC13). vmaX: 1401 w, 1333 TV, 1304 m, 1263 m, 1100 vs, 1020 vs, 855 w, 803 Yb, 763 vs cm-1. Reaction of this complex with carbon monoxide produced Rh( CO)CI(Sb(CaH5)3)4. Anal. Calcd for C73HsoSb4OClRh: C, 55.53; H, 3.83; C1, 2.24. Found: C, 55.56; H, 4.21; C1, 2.89. RhCl( C~FB)( Sb(CGHJ)~)Z .-Hexafluorobut-2-yne was condensed into a n evacuated, thick glass tube containing RhC1(Sb( C6Hd)3)3 (0.3 g ) which had been completely dissolved in dry benzene ( 5 ml). T h e tube was sealed and held a t 75-80' for 3 hr. The tube n a s then cooled, left t o stand 24 hr, and opened, and the excess fluorocarbon was recovered. The crude crystalline product waS filtered off and recrystallized from 1,l-dichloroethane-petroleum ether (bp 30-60') affording yellow-orange crystals, mp 208-210' dec (0.23 g, 80%). Anal. Calcd for C44H30Sb2F12ClRh: C, 45.2; H, 2.6; F, 19.5; molwt, 1170. Found: C, 44.9; H , 2.7; F, 20.4; molwt,